Facile approach to N,O,S-heteropentacycles via condensation of sterically crowded 3H-phenoxazin-3-one with ortho-substituted anilines

A convenient method for the synthesis of a series of 2-(arylamino)-3H-phenoxazin-3-ones based on the nucleophilic substitution reaction between sterically crowded 3H-phenoxazin-3-one and arylamines performed by short-term heating of the melted reactants at 220–250 °C is described, and the compounds were characterized by means of single-crystal X-ray crystallography, NMR, UV–vis, and IR spectroscopy, as well as cyclic voltammetry. The reaction with o-amino-, o-hydroxy-, and o-mercapto-substituted arylamines widened the scope and provided an access to derivatives of N,O- and N,S-heteropentacyclic quinoxalinophenoxazine, triphenodioxazine and oxazinophenothiazine systems.

involves the coupling of 3H-phenoxazin-3-ones with variously functionalized aromatic amines.This is followed by the cyclization of the initially formed adducts [10][11][12].At the first stage, this reaction follows one of three possible reaction pathways, including Schiff base formation (attack at the C(3) center), Michael addition at C(1), or nucleophilic substitution (S N H) at the C(2) center [13][14][15].Most readily used is the pathway involving carbonyl-amine condensation and Schiff base formation, which is then cyclized [12,16].The reaction of 1 with arylamines 2a is performed in toluene solution in the presence of a catalytic amount of p-toluenesulfonic acid.This readily affords 6,8-di-tert-butyl-N-aryl-3H-phenoxazin-3-imines 3 but proceeds smoothly only with highly basic amines (Scheme 1) [6].The choice for one of the other two possible reaction pathways (nucleophilic additions to either the C(1) or C(2) center) critically depends on the electrophilicity.Figure 1 shows the distribution of electronic density in 6,8-di-tert-butyl-3Hphenoxazin-3-one (1).This is also the basic compound used in the transformations that are studied in this work due to the high kinetic stability and good solubility ensured by the tert-butyl groups.The largest positive charge of the C(1)-C(2)-C(3) segment is concentrated at the C(2) atom.The charge at the other electrophilic center C(1) of 1 is much lower.
It comes, therefore, with no surprise that the interaction of arylamines and the 5-hydroxy and 5-acetoxy derivatives of 3H-phenoxazin-3-one is directed toward the C(2) reaction center to yield 2-amino-3H-phenoxazin-3-ones as the final products under aerobic conditions.The reactions proceed readily in refluxing acidified (pK a = 1-5) ethanol solutions of the amine hydrochlorides to give 2-monosubstituted derivatives of 3H-phenoxazin-3-ones in a moderate yield [10,17].In the present work, we intended to explore the reaction of 3H-phenoxazin-3-ones with aromatic amines, the direction of which is controlled by the large positive charge at the C(2) center of the p-quinone imine moiety of the heterocycle.With this in mind, we turned our attention to solid-state organic reactions.Numerous examples of nucleophilic substitutions at carbon centers are discussed in comprehensive reviews [18,19], but none is directly related to aromatic S N H reactions.The developed procedure was applied to the synthesis of compounds 4 and extended to arylamines with o-amino, o-hydroxy, and o-mercapto substituents, providing access to N-, O-, and S-containing heteropolycyclic structures.

Results and Discussion
We found that a convenient way toward 6,8-di-tert-butyl-2-(arylamino)-3H-phenoxazin-3-ones 4 involves the short-term heating (30 min) of a molten mixture of 1 and an arylamine at 250 °C, followed by purification of the products by column chromatography.No preliminary grinding of the crystalline samples, which is otherwise typical for solid-state reaction, was employed in this case.As seen in Scheme 2, the nucleophilic substitution reaction occured in good yield and with no restrictions in terms of amine basicity.
The compounds 4a-h intensely absorb light in the spectral range of 400-550 nm, with maxima at 439-459 nm, ε = 20600-37100 M −1 ⋅cm −1 (Figure 3 and Table 1).The introduction of an amino group into the p-position of the N-phenyl fragment gave rise to the appearance of an additional long-wavelength absorption band with λ max = 520 nm and ε = 9200 M −1 ⋅сm −1 .Subjecting o-phenylenediamines 2с to the reaction with 3H-phenoxazin-3-one makes the simultaneous activation of two principle reaction pathways (S N H and Schiff base formation) possible.By using a similar procedure to that applied to the syn-  The nitrogen atoms in the oxazine and pyrazine rings of 5, N(7), N (12), and N( 14), offer three possible positions for the N-H proton.Therefore, three tautomeric forms are possible for 5 (Scheme 4), one of which, the 7H-tautomer 7b, inevitably adopts a bipolar or biradical structure.According to the data from the DFT calculations performed at the B3LYP/6-311++G(d,p) approximation (Figure S6, Supporting Information File 1), the energetically preferred tautomer is the 14Hform 7a.The least stable 7H-isomer 7b conforms to a minimum on the corresponding potential energy surface.However, the stable wave function of 7b corresponds to an electronic state with a broken symmetry [20], indicating the presence of two unpaired electrons and the singlet biradical form.
The structure of the newly synthesized compounds 5, which are derivatives of a previously unknown 14Н-quinoxaline[2,3b]phenoxazine system 7a, was unambiguously established based on COSY, HSQC, and HMBC NMR-spectroscopic data.Further, the 15 N NMR spectrum of 5a confirmed the typical pyrrole-like character of the N(12) atom as well as the pyridinelike character of the N (7) and N( 14) atoms (Figure S31, Supporting Information File 1) [21,22].The molecular structure of 5c was also determined using X-ray crystallography (Figure 4).
We assumed that the scope of the reaction shown in Scheme 3 could be expanded via replacement of one of the amino groups of o-phenylenediamine by another strong nucleophilic center.It was earlier found [23] that condensation of 3H-phenoxazin-3one (1) with various o-aminophenols (in refluxing DMF for 8-10 h), upon formation of the corresponding imine intermediate, affords benzo [5,6]      ters are close to those recorded for triphenodioxazines [23].The energy of the HOMO and LUMO orbitals assessed on the basis of the CV and electronic absorption spectral data are given in Table 3.

Conclusion
The diverse reactions of 3H-phenoxazin-3-one derivatives with nucleophilic reagents are primarily directed toward the p-quinone imine fragment [5,13,15].In the presence of protonic acids, the reaction with amines proceeds through Schiff base formation [6].In turn, without an acidic catalyst, it is driven by the distribution of the electron density (Figure 1), such that the nucleophilic attack occurs at the most electrophilic C(2) center.With this in mind, we presented a convenient procedure for the S N H reaction of aromatic amines with sterically crowded 6,8di-tert-butyl-3H-phenoxazin-3-one (1) that afforded a series of 6,8-di-tert-butyl-2-(arylamino)-3H-phenoxazin-3-ones 4 prepared in 68-93% yield (Scheme 2).Using o-amino-, o-hydroxyand o-mercapto-substituted anilines in this process allowed to pursue both principal reaction pathways (Schiff base formation and S N H), which led to the formation of derivatives of the previously unknown 14Н-quinoxaline[2,3-b]phenoxazine system 5 (Scheme 3) as well as N,O-and N,S-heteropentacyclic tripheno- dioxazines and oxazinophenothiazine 10a-c.The structural assignment [10,11] of the N,O-containing reaction products as 12H-quinoxaline[2,3-b]phenoxazines was confirmed through DFT calculations, X-ray crystallography, and NMR spectroscopy.
Electronic absorption spectra (Table 2 and Figures 5-7) and electrochemical properties (Table 3) of the heteropentacyclic compounds 4a-h, 5a-c, 6a,b, and 10c revealed potential for testing as potential donors for organic solar cells or as dye sensitizers for dye-sensitized solar cells [24,25].

Experimental
All reagents and solvents were purchased from commercial sources (Aldrich) and used without additional purification.The compounds were characterized by 1 H, 13 C, and 15 N NMR spectroscopy (NMR spectra of compounds 4a-h, 5a-c, 6a,b, and 10c are given in Figures S13-S43, Supporting Information File 1), mass spectrometry (Figures S44-S56, Supporting Information File 1), IR and UV-vis spectroscopy, as well as elemental analysis.The NMR spectra were recorded on the spectrometers Varian UNITY-300 (300 MHz for 1 H) and Bruker AVANCE-600 (600 MHz for 1 H, 151 MHz for 13 C, and 60 MHz for 15 N) in CDCl 3 solutions.Chemical shifts are reported in ppm using the residual solvent peaks as reference (7.24 ppm for 1 H, 77.0 ppm for 13 C, and 384 ppm for 15 N using nitromethane).Chemical shifts were measured with a precision of 0.01 ppm, and 0.1 Hz for spin-spin coupling constants J.The assignment of resonance peaks was carried out using COSY, HSQC, and 1 H, 13 C as well as 1 H, 15 N HMBC.Melting points were determined using a PTP (M) apparatus and were left uncorrected.IR spectra were recorded on a Varian Excalibur 3100 FTIR instrument using the attenuated total internal reflection technique (ZnSe crystal).UV-vis spectra were recorded at c = 2⋅10 −5 M in toluene solutions with a Varian Cary 100 spectrophotometer.Photoluminescent spectra were recorded at c = 2⋅10 −5 M (compounds 5a-c and 6a,b) and c = 2⋅10 −6 M (compound 10c) in toluene solutions with a Varian Cary Eclipse fluorescence spectrophotometer.UV-vis and fluorescence spectra were recorded using standard 1 cm quartz cells at room temperature.Toluene of spectroscopic grade (Aldrich) was used to prepare the solutions.The fluorescence quantum yield was determined relative to quinine bisulfate in 0.05 M H 2 SO 4 as standard (Φ F = 0.52, excitation at 365 nm for 5a-c and 6a,b) [26] and cresyl violet perchlorate in ethanol (Φ F = 0.54, excitation at 510 nm for 10c) [27].Mass spectrometric analysis was performed on a Bruker UHR-TOF Maxis™ Impact (resolving power (FWHM) of 40,000 at m/z 1222, electrospray ionization).
The cyclic voltammograms of 4a-h, 5a-c, 6a,b, and 10c were measured with the use of three-electrode configuration (glassy carbon working electrode, Pt counter electrode, Ag/Ag + reference electrode using 0.01 M AgNO 3 in CH 3 CN) in CH 2 Cl 2 (4a-h), CH 3 CN (5a-c, 6a,b, and 10c) and potentiostat-galvanostat Elins P-45X.X-ray data collection was performed on an Agilent SuperNova diffractometer using a microfocus X-ray source with copper anode (Cu Kα radiation, λ = 1.54184Å) and Atlas S2 CCD detector.The diffraction data of 4c,d,f, 5c, and 10b were obtained at 100 K. Crystals of 5c were obtained in the form of a solvate with molecules of isopropanol and water present.The protons attached to heteroatoms were localized by difference Fourier synthesis and refined with isotropic thermal parameters.The collection of reflexes as well as the determination and refinement of unit cell parameters were performed by using the specialized CrysAlisPro 1.171.38.41 software suite [28].The structures were solved by using the SHELXT program [29].Structural refinement was performed with the SHELXL program [30].Molecular graphics were rendered and prepared for publication with the Olex2 version 1.3.0software suite [31].The complete X-ray diffraction datasets were deposited in the Cambridge Crystallographic Data Center (CCDC numbers 2292841, 2292840, 2292847, 2308520, and 2292848, Tables S2-S9, Supporting Information File 1).The DFT calculations [32] were performed using the Gaussian 16 program package [33] with the B3LYP functional [34] and the 6-311++G(d,p) basis set.
The structures corresponding to minima on the potential energy surface and states with broken symmetry [20] were found through complete optimization of the geometry without imposing symmetry restrictions, followed by analyzing the stability of the DFT wave function.The images of the molecular structures in Figure 1 and Figure S6, Supporting Information File 1, were obtained using the Chemcraft program [35].

Table 2 :
UV-vis absorption and fluorescence emission data of compounds 5a-c, 6a,b, and 10c in toluene.
a Fluorescence quantum yield.b Shoulder.